Delivering 27mer DsiRNAs to Mice DRGs

I have been a proponent of using 27mer DsiRNAs (Dicer Substrate Small Interfering RNAs) with our i-Fect kits to deliver siRNA to the CNS for gene expression analysis. The potency of this platform was highlighted in my profile of Dr. Mark Behlke.

It was further confirmed  in Studies conducted by Dr. Philippe Serrat and his team at University of Sherbrooke.

Louis Doré-Savard, Geneviève Roussy, Marc-André Dansereau, Michael A Collingwood, Kim A Lennox, Scott D Rose, Nicolas Beaudet, Mark A Behlke and Philippe Sarret. Central Delivery of Dicer-substrate siRNA: A Direct Application for Pain Research. Molecular Therapy (2008); Jul;16(7):1331-9. Epub 2008 Jun 3 doi:10.1038/mt.2008.98.

Using ultra low dose of DsiRNAs complexed with Neuromics’  i-Fect , they were able to successfully reduce NTS2 gene expression by up to 86% in rat lumbar Dorsal Root Ganglia after only two intrathecal injections. This was confirmed by Western Blot and qPCR analysis.

We now have further confirmation of the capabilities of this delivery platform in a just released publication by Dr. Jeffrey Mogil and team:

Michael L. LaCroix-Fralish, Gary Mo, Shad B. Smith, Susana G. Sotocinal, Jennifer Ritchie, Jean-Sebastien Austin, Kara Melmed, Ara Schorscher-Petcu, Audrey C. Laferriere, Tae Hoon Lee, Dmitry Romanovsky, Guochun Liao, Mark A. Behlke, David J. Clark, Gary Peltz, Philippe Séguéla, Maxim Dobretsov and Jeffrey S. Mogil. The β3 subunit of the Na+,K+-ATPase mediates variable nociceptive sensitivity in the formalin test. doi:10.1016/j.pain.2009.04.028.

IT Delivery of siRNA in vivo supplement

Dicerna Makes Progress

Just wanted to update you on my friends at Dicerna…from in vivo blog…

Wednesday, October 31, 2007

Dicerna Crashes RNAi Party

Life often imitates art, as the saying goes.

In “This Is Spinal Tap,” the classic rock and roll mockumentary chronicling the eponymous band, guitarist Nigel Tufnel famously brags that his amplifiers, unlike conventional ones that max out at a volume of ten, were specially designed to go “one louder.”

“These go to eleven,” he deadpans.

IN VIVO Blog has learned that in the world of RNA interference (RNAi), a new company aims to make some noise of its own not by going louder, but longer, while at the same time circumventing the IP barriers to entry in the exciting field.

Dicerna Pharmaceuticals Inc. is based on technology called Dicer substrate small interfering RNAs developed by co-founders John Rossi, PhD, from the City of Hope National Medical Center’s Beckman Research

Dr. Mark Behlke

Dr. Mark Behlke

Institute and Mark Behlke, MD, PhD, from Integrated DNA Technologies Inc. (IDT). Dicer substrate siRNAs differ from traditional siRNA employed by companies like Alnylam Pharmaceuticals and Merck & Co.’s Sirna Therapeutics in that they are slightly longer oligonucleotides—between 26 and 30 base pairs (bp) versus 21bp for standard siRNA—which then get trimmed down to size once inside the cell. 

Dicerna is expected to announce its $13 million Series A, which will be led by Oxford Bioscience Partners, at some point in November.

Dicerna hopes that its longer molecules not only confer an IP workaround strategy in the hot area of RNA interference therapeutics, but also a pipeline of highly potent drug candidates that will pique the interest of quite a few Big Pharma that have been so far left out of the increasingly expensive but important RNAi arms race.

I will continue to publish updates on this “arms race”.

The First Story is Here!

Dr. Mark Behlke and 27mer DsiRNAs

 

I am pleased to be featuring Dr. Mark Behlke’s story as our first. This was an easy choice because our main characters, Mark and the 27mer DsiRNAs (Dicer Substrate Small Interfering RNAs), are rising stars in small interfering (siRNA) based research.

 

siRNAtechnology addresses the need for Biosciences Researchers and Clinicians to selectively reduce expression in genes of interest. If effectively delivered, these siRNAs act as “dimmer” or “off” switches for gene expression (gene silencing). Traditionally, synthetic 21mer RNA duplexes have been employed to trigger RNA interference, a method that was pioneered by Tuschl and colleagues in 2001.

 

I became interested in Mark’s work in 2003. Our collaboration was catalyzed by Neuromics’ need to provide our customers better ways to deliver siRNAs to neurons in vitro and in vivo using our i-Fect ™  transfection kits. Successful outcomes for our customers hinged on the potency and duration of gene silencing. In short, our customers needed potent knockdown reagents and optimized ways to deliver these reagents to neurons, both in vivo and in vitro.

 

Mark has gone above and beyond the call of duty in addressing this need. His investment of time and his company’s resources (Integrated DNA Technologies) has proven to be a linchpin in successful Neuroscience Research outcomes and has resulted in exciting publications for several of our key customers.

About Dr. Mark Behlke

 

Dr. Mark Behlke is the Chief Scientific Officer (CSO) at Integrated DNA Technologies (IDT) and has been directing R&D activities of their Molecular Genetics & Biophysics research groups since 1996.  Dr. Behlke (with Dr. John Rossi, from the Beckman Research Institute at the City of Hope) is a scientific co-founder of Dicerna Pharmaceuticals.  Previously, Dr. Behlke was a HHMI Physician Postdoctoral Fellow at the WIBR in the laboratory of Dr. David Page and a Resident Physician in Internal Medicine at Brigham and Women’s Hospital, Boston.  He received his MD/PhD degrees from Washington University, St. Louis in 1988, where he studied immunogenetics in the laboratory of Dr. Dennis Loh.  He received his B.S. degree from the Massachusetts Institute of Technology in 1981.

 

Contact information:

Mark Behlke M.D., Ph.D,Chief Scientific Officer

 

Integrated DNA Technologies, Inc.

1710 Commercial Park

Coralville, IA  52241

USA

 

800-328-2661

319-626-8432 office

319-626-9621 fax

mbehlke@idtdna.com website: http://www.idtdna.com/


My goal here is to spread the story of 27mer DsiRNAs. This technology has proven an effective tool for my Neuroscience Research Customers. With continued development, this could become a cornerstone of functional genomics.
                          

The Back-story 

Where it starts

A lot has to happen right for siRNA to reduce expression of mammalian genes. The siRNA molecules must first   be transfected into the cells of interest. Once inside, they must be correctly processed by the cells’ biochemistry

Our story starts with Mark’s curiosity concerning siRNA length and what happens to these molecules inside the cell. The idea was to systematically study the effects of varying siRNA length on triggering gene silencing. This project was done in collaboration with Dr. John J. Rossi (Beckman Research Institute) and other members of his lab at the City of Hope National Medical Center (most notably Dr. Dongho Kim, a postdoc in the Rossi lab).

The team knew that mammalian cells use a Dicer complex to process longer length dsRNAs into functional 21mer siRNAs and then feed these into a complex called “RISC” (RNA induced silencing complex).   

Long RNAs (several hundred bases) can be introduced into worms or flies and trigger RISC. 

In mammals, the introduction of similar long RNAs triggers immune responses and cell death Use of small 21mer siRNAs mostly avoids this problem and permits use of RNAi in mammals This traditional approach made sense given the siRNA-Dicer-RISC pathway (fig. 1). The team looked at the effects of transfecting into cells synthetic dsRNAs ranging in length fom 21mers to 30mers

 

Fig. 1: Pathways in siRNA .  Long vs. short dsRNAs are differentially processed as shown.

What happened? Was 21mer length optimal?

Their findings were quite unexpected: they observed that synthetic RNA duplexes 25–30 nucleotides in length could be up to 100-fold more potent than corresponding 21mer siRNAs. Why?  The 27mers were later shown to be a substrate for Dicer, and were processed down to 21mer size. Drs. Rossi and Behlke theorize that increased potency may result from forcing the system to interact with Dicer, which then invokes a natural RISC loading pathway that is denied to 21mer RNAs.  The 27mers “primed the Dicer pump”, resulting in better access of the 21mer product for RISC.

This meant that less siRNA would be needed for gene silencing – i.e., that the RNAs were more potent and could be used at lower dose. Important for many reasons among them less toxicity and lower research expense.

Please see: Dong Ho Kim, Mark Behlke, Scott Rose, Mi-Sook Chang, Sangdun Choi & John Rossi. Synthetic dsRNA Substrates Enhance SiRNA Potency and Efficacy  Nature  Biotechnology. Published online 26 December 2004;doi10.1038/nbt1051.

The rest of the story

Great news! The 27mers were more potent and could prove a better tool for Researchers studying gene function. It’s never that easy. While potency of the 27mer DsiRNAs proved greater than the 21mers in many assays, Mark shared that results proved frustratingly unpredictable depending on the target. More insight was needed.

As Mark and the team gained more experience by targeting additional sites in other genes, examples were found where the 27mer DsiRNAs had greater, the same or less potency than 21mers siRNAs for the same site. This wide variation in performance resulted from differences in dicing patterns: sometimes Dicer processing resulted in a “good” 21mer product for RISC and sometimes resulted in “bad” products.

The root cause of this unpredictability proved to lie in the design of the synthetic 27mers. The original designs were blunt ended (both ends) and Dicer processing was unpredictable – essentially random – and the precise 21mer cleaved out of the 27me parent varied from sequence to sequence. This forced the team to learn how to design better 27mers that have predictable Dicer cleaving patterns.  The new improved design is a 27mer asymmetric duplex having a single 2-base 3’-overhang on one end and 2 DNA bases on the opposing blunt end.

 

Rose SD, Kim DH, Amarzguioui M, Heidel JD, Collingwood MA, Davis ME, Rossi JJ, Behlke MA. Functional polarity is introduced by Dicer processing of short substrate RNAs. Nucleic Acids Res. 2005 Jul 26;33(13):4140-56. Print 2005. PMID: 16049023

 

Also  see: 27mer RNA Duplexes as Triggers of RNAi. Exploiting the Biochemistry of Dicer. BIOforum Europe 06/2006, pp 25–27, GIT VERLAG GmbH & Co. KG, Darmstadt, Germany.

 

 

The proof

 

So now we have optimal 27mer DsiRNAs, let’s put them work in the CNS with i-Fect ™ .

 

IDT and Neuromics collaborated with Philippe Sarret at the University of Sherbrooke Neuroscience Center. Philip and his teamed selected Integrated DNA Technologies’ designed 27mers DsiRNAs and i-Fect as core research tools for their proof of concept. They wanted to prove that an RNAi approach could be used to study pain pathways in rats in his lab by selective knockdown of specific CNS receptors via direct injection of DsiRNA (formulated in i-Fect) into the spinal cord of rats.

 

Their recently published findings were remarkable.

 

Please see: Louis Doré-Savard, Geneviève Roussy, Marc-André Dansereau, Michael A Collingwood, Kim A Lennox, Scott D Rose, Nicolas Beaudet, Mark A Behlke and Philippe Sarret. Central Delivery of Dicer-substrate siRNA: A Direct Application for Pain Research. Molecular Therapy (2008); Jul;16(7):1331-9. Epub 2008 Jun 3   doi:10.1038/mt.2008.98.

 

Low dose DsiRNA (0.005 mg/kg) was highly effective in reducing the expression of the Neurotensin receptor-2 (NTS2, a G-protein-coupled receptor (GPCR) involved in ascending nociception) in rat spinal cord through intrathecal (IT) administration formulated with the cationic lipid i-Fect. Along with specific decrease in NTS2 mRNA and protein, the results showed a significant alteration in the analgesic effect of a selective-NTS2 agonist, reaching 93% inhibition up to 3–4 days after administration of DsiRNA.

 

In order to ensure that these findings were not biased by unsuspected off-target effects (OTEs), the team also demonstrated that treatment with a second NTS2-specific DsiRNA also reversed NTS2-induced antinociception, and that NTS2-specific 27-mer duplexes did not alter signaling through NTS1, a closely related receptor.

 

Mark’s Vision

 

This story has no end point because the key players are continuing to collaborate and march forward on their journey of discovery. Mark said it best, “Discovering new stuff is why I do what I do. It’s nice if the findings are interesting, but it is better if it has the potential to impact the world and improves people’s lives in some way.”  The basic biology studied now may lead to new generations of drugs tomorrow that treat problems that cannot be effectively treated today.

 

The good news is most of the story lies ahead. In fact, Biotech Companies are being formed and funded on the promise of 27mer DsiRNAs’ potential both as a platform for drug development and as actual therapeutics.  For an example, please visit Dicerna Pharmaceuticals.

 

Who knows… someday, 27mers DsiRNAs could be the key for curing Neurodegenerative and other Diseases. Stay tuned.

Dr. Behlke’s 27mer DsiRNA Story Coming Soon

Learn the News Behind the News on 27mer DsiRNA. Includes the story of the how the potentcy of 27mer siRNA was discovered and exiting developments regarding the understanding of the role of the Dicer Complex and RISC. Also featured will be advances in 27mer oligo design and how the technology is being used in basic research and drug discovery.

Here’s a publication highlighting the roots of the story:

Dong Ho Kim, Mark Behlke, Scott Rose, Mi-Sook Chang, Sangdun Choi & John Rossi. Synthetic dsRNA Substrates Enhance RNAi Potency and Efficacy Nature Biotechnology. Published online 26 December 2004;doi10.1038/nbt1051.

 

Announcing our first story: Dr. Mark Behlke

Story to be published July 11, 2008.

Dr. Behlke, his team and collaborators are working on improving the delivery of Dicer-substrate siRNAs (DsiRNAs) in vitro and in vivo.

His work has helped establish siRNA technology as a viable tool for drug development.

Please see the article titled RNAi Researchers Galvanized by Advances: Technology’s Viability in Drug Development Is Finally Established by Elizabeth Lipp.

It appeared in the June 1, 2008 issue of Genetic Engineering & biotechnology News.

Here’s a notable quote from Dr. Behlke:

Long dsRNAs have been employed for many years as a means to modulate gene expression in plants, yeast, and C. elegans. Similar attempts in higher organisms failed due to interferon activation, however we now know that short RNA duplexes can be safely used in mammalian systems both in vitro and in vivo.

The technology has rapidly matured, thanks in large part to all that was learned over the past 20 years using antisense oligonucleotides. RNAi is now routinely employed in vivo as an experimental tool and numerous groups are vigorously pursing the use of RNAi compounds as therapeutics. Several siRNA drugs are already in clinical trials and more are in preclinical development.

My first “News Behind the News” story posted to this Neuromics blog will feature Dr. Mark Behlke, CSO, Integrated DNA Technologies.